Glucocorticoid action on the immune system

Glucocorticoids have profound effects on immune function that are mediated, in part, by steroid-induced cell death. Our studies have been aimed at identifying the mechanism of this lymphocytolytic process using the rat thymocyte as a model system. Administration of glucocorticoids in vivo resulted in internucleosomal cleavage of the lymphocyte genome that was detectable within 2 h of treatment and increased with time after hormone administration. Six h after steroid treatment greater than 50% of the genome was degraded, yet cell viability remained greater than 90% indicating that this event preceded cell death. Furthermore, this process appeared to be mediated by the glucocorticoid receptor since the antagonist RU 486 blocked glucocorticoid-mediated DNA degradation. To further characterize this lymphocytolysis we have analyzed glucocorticoid-treated thymocytes for nucleases. Two families of nuclear proteins have been identified, a 30-32 kDa doublet and a series of 3-4 proteins that are 12-19 kDa, both of which are induced by glucocorticoid treatment (137 +/- 6% and 342 +/- 24%, respectively) and have prominent nuclease activity. These nucleases can also be induced in vitro indicating that glucocorticoids act directly on thymocytes to mediate this response. Moreover, this nuclease induction, like glucocorticoid-mediated DNA degradation, could be blocked by RU 486. Based on these findings we propose a working model of glucocorticoid-mediated lymphocytolysis in which these steroids, acting via a receptor mediated process, induce the expression of a lysis gene product (nuclease) which degrades the genome and results in cell death.     

Identification and characterization of glucocorticoid-regulated nuclease(s) in lymphoid cells undergoing apoptosis

Apoptosis is a physiological process by which selected cells are deleted from a population in response to specific regulatory signals. A hallmark of apoptosis is the internucleosomal degradation of DNA prior to cell death. We are studying glucocorticoid-induced lymphocytolysis as a model system for apoptosis within the immune system. In rat thymocytes, the internucleosomal DNA cleavage which occurs following glucocorticoid treatment is both time- and dose-dependent, and is blocked by the glucocorticoid antagonist RU 486, indicating that this effect is mediated by the glucocorticoid receptor. Similar experiments using glucocorticoid-responsive (wt) and glucocorticoid-resistant (nt⁻) S49.1 lymphoma cell lines confirm that internucleosomal DNA degradation and cell death are glucocorticoid receptor-mediated events and thus reflect the direct effects of glucocorticoids on lymphocytes. In an effort to identify the nuclease(s) responsible for the DNA degradation, we have developed two assays to detect nucleases whose activity is altered by glucocorticoid treatment. The first assay involves electrophoresing extracts of nuclear protein from control and glucocorticoid-treated lymphoid cells into SDS-polyacrylamide gels containing [³²P]DNA within the gel matrix. This assay is used to estimate the molecular mass of the nuclease, based on the observed in situ nuclease activity. The second assay uses HeLa nuclei as a substrate to detect internucleosomal cleavage activity present in nuclear extracts of control and glucocorticoid-treated lymphoid cells. Using these assays we have identified a novel Ca²⁺, Mg²⁺-dependent nuclease with an apparent molecular weight of 18 kDa in both S49 wt cells and rat thymocytes treated with glucocorticoids. Furthermore, nuclear extracts of glucocorticoid-treated, but not control, rat thymocytes and S49 wt cells were capable of cleaving HeLa chromatin at internucleosomal sites. In an effort to determine the identity of the nuclease capable of internucleosomal cleavage of DNA, nuclear extracts from dex-treated rat thymocytes were fractionated by gel filtration chromatography under non-denaturing conditions, and the fractions were analyzed using the [³²P]DNA SDS-PAGE and HeLa nuclei assays. When analyzed under native conditions, the 18 kDa nuclease described previously appears to exist as a 25 kDa protein which may be part of a high molecular weight complex. Interestingly, only the 25 kDa form of the protein was associated with internucleosomal DNA cleavage activity where as the high molecular weight form of the enzyme was devoid of this activity.     

Glucocorticoid-induced lymphocytolysis is not mediated by an induced endonuclease

The mechanism of glucocorticoid-induced internucleosomal DNA cleavage and cytolysis of lymphatic cells is not known. Recent data (Compton, M.M., and Cidlowski, J.A. (1987) J. Biol. Chem. 262, 8288-8292) suggested that in vivo treatment of rat thymocytes with glucocorticoids induces a nucleolytic "lysis gene" product(s) responsible for lymphocytolysis. In this paper, the possibility that lymphocytolysis may result from glucocorticoid-induced nuclease(s) was examined. Using the rat thymocytes as a model system, we have shown by electrophoretic, enzymatic, and amino acid sequence analysis that the putative glucocorticoid-induced nucleases identified recently by Compton and Cidlowski are in fact H1, H1(0), and core histones, and their gross appearance is not the result of new histone protein synthesis, but a result of the release of histone-containing nucleosomes during chromatin breakdown. Evidence presented here shows that the putative induced nuclease activity is an artifact of the assay system employed. Because our data do not support induction of a glucocorticoid-induced nuclease(s), we examined the possibility that DNA cleavage might be induced by activation of a constitutive endogenous endonuclease. We have shown that it is possible to produce characteristic internucleosomal DNA cleavage of rat thymocytes, merely by incubating intact nuclei from untreated adrenalectomized rat thymocytes with Ca2+ and Mg2+ for a short period of time. However, in glucocorticoid-sensitive human CEM-C7 lymphocytes activation of internucleosomal DNA cleavage was independent of calcium uptake. We conclude that glucocorticoid induction of internucleosomal DNA fragmentation does not necessarily require expression of a new nuclease(s), but is the result of the activation of a constitutive endogenous endonuclease(s). Also, our data suggest that the mechanism which controls activation of internucleosomal DNA cleavage in rat thymocytes differs from that which operates in CEM-C7 lymphocytes.     

Similar actions of glucocorticoids and calcium on the regulation of apoptosis in S49 cells

Glucocorticoid-induced lymphocyte cell death is a programmed process which is thought to involve the calcium-dependent degradation of DNA into multiples of 180 basepairs, characteristic of internucleosomal degradation. We have used the glucocorticoid-sensitive mouse lymphoma cell line S49.1 [wild-type (wt)] and the glucocorticoid-resistant cell line S49.22r (nt-) to evaluate the role of both glucocorticoid receptors and calcium in the regulation of internucleosomal DNA degradation and expression of calcium-dependent deoxyribonuclease activity. DNA was isolated from untreated (control) and dexamethasone (dex)-treated viable cells and analyzed for internucleosomal DNA degradation by agarose gel electrophoresis, followed by ethidium bromide staining. Glucocorticoid treatment resulted in substantial internucleosomal DNA degradation in wt cells, but not in nt- cells. This effect was inhibited by coincubation of cells with dex and the glucocorticoid receptor antagonist RU486. In contrast to the glucocorticoid response, administration of either of two calcium ionophores, ionomycin or A23187, produced internucleosomal degradation of DNA in both wt and nt- cells, although the latter were less sensitive to ionophore treatment. Interestingly, A23187 treatment also resulted in a loss of cell viability in HeLa S3 cells, a cell line that does not exhibit glucocorticoid-induced apoptosis. No internucleosomal DNA degradation was detected in HeLa S3 cells killed by A23187. To determine whether similar nucleases are associated with this internucleosomal DNA degradation resulting from both glucocorticoid and calcium ionophore treatment, 0.3 M NaCl nuclear protein extracts were prepared from control and treated cells and analyzed for protein composition or nuclease activity. To assay for nuclease activity, nuclear extracts were electrophoresed in sodium dodecyl sulfate-polyacrylamide gels impregnated with [32P]DNA. Nuclease activity was detected by removal of sodium dodecyl sulfate from the gel, activation with calcium, and subsequent visualization of the loss of [32P]DNA by autoradiography. Dex treatment of wt cells resulted in the appearance of several proteins within the mol wt range of 12-18 kDa, only one of which (16-18 kDa) exhibited calcium-dependent nuclease activity. The appearance of these proteins in nuclear extracts was inhibited by coincubation of glucocorticoid-treated cells with RU 486. Glucocorticoid treatment did not result in the appearance of nuclease activity in nuclear extracts from nt- cells. Interestingly, A23187 or ionomycin treatment resulted in an increase in activity of the 16- to 18-kDa nuclease in both wt and nt- cells. These findings indicate that both glucocorticoid receptors and calcium may share common features in the regulation of apoptosis in lymphoid cells.     

Development of an apoptosis endonuclease assay.

A biochemical hallmark of cells undergoing programmed cell death, or apopotosis, is the endonucleolytic cleavage of genomic DNA at internucleosomal sites. To study further the nuclease involved in this process, an assay system was developed to measure internucleosomal DNA degradation. Micrococcal nuclease (MNase), a bacterial enzyme that cleaves chromatin at internucleosomal intervals, was used to validate the assay procedure. Thymocyte nuclear proteins obtained from glucocorticoid-treated chickens, a source of internucleosomal DNA-degrading activity, were incubated with chicken red blood cell nuclei, and genomic DNA was subsequently extracted and analyzed by agarose gel electrophoresis. Generation of internucleosomal DNA degradation products by the thymocyte protein extract required ATP and was both time and protein concentration dependent. This nuclease activity could be inhibited by EDTA, EGTA, alkylating agents, or heat denaturation. Addition of purified proteinases, RNases, or other types of nucleases to the assay failed to generate discrete internucleosomal lengths of DNA, thus confirming the nuclease specificity of this assay. On the basis of these data, we believe that this assay system will be instrumental in isolating and characterizing the nuclease(s) associated with apoptosis.     

Utilization of an in vitro assay to evaluate chromatin degradation by candidate apoptotic nucleases

Apoptosis is commonly associated with the catabolism of the genome in the dying cell. The chromatin degradation occurs in essentially two forms: (1) internucleosomal DNA cleavage to generate oligonucleosomal-length fragments (180-200 bp and multiples thereof), and (2) cleavage of higher order chromatin structures to generate approximately 30-50 Kb fragments. To investigate this component of apoptosis and identify the nuclease(s) responsible, we have developed and utilized an in vitro assay that recapitulates the genomic destruction seen during apoptosis in vivo and allows the simultaneous analysis of both forms of DNA degradation from the same sample. Using this assay we evaluated the digestion patterns of several candidate apoptotic nucleases: DNase I, DNase II, and cyclophilin (NUC18) as well as the bacterial enzyme micrococcal nuclease (not thought to be involved in apoptosis). Chromatin degraded by DNase I formed a smear of DNA on conventional static-field agarose gels and approximately amp;30 - 50 Kb DNA fragments on pulsed field gels. In contrast, DNase II, at a physiologically relevant pH, had no effect on the integrity of HeLa chromatin in either analysis. Similar to DNase I, cyclophilin C produced only approximately 30-50 Kb DNA fragments but did not generate internucleosomal fragments. In contrast, micrococcal nuclease generated both oligonucleosomal and approximately 30-50 Kb DNA fragments. Nuclear extracts from glucocorticoid-treated apoptotic thymocytes generated oligonucleosomal DNA fragments and the larger approximately 30-50 Kb DNA fragments, fully recapitulating both types of apoptotic DNA degradation. Previously, differential sensitivity of nucleases to inhibition by Zn2+ was used to argue that two distinct enzymes mediate approximately 30-50 Kb DNA cleavage and internucleosomal DNA degradation. While, the nuclease activity present in thymocyte nuclear extracts was differentially sensitive to inhibition by Zn2+ during short term incubations it was not during prolonged digestions, suggesting that differences in DNA detection are likely to account for previous results. Together our studies show that none of the nucleases commonly associated with apoptosis could fully recapitulate the DNA degradation seen in vivo.     

Activation of internucleosomal DNA cleavage in human CEM lymphocytes by glucocorticoid and novobiocin. Evidence for a non-Ca2(+)-requiring mechanism(s)

Internucleosomal DNA cleavage is the key molecular event of the cytolytic phase of glucocorticoid-induced lymphocytolysis. We find that novobiocin, the topoisomerase II inhibitor, is a potent inducer of in vivo internucleosomal DNA cleavage in human CEM lymphocytes. This in vivo effect is very rapid, time- and dose-dependent, requires cellular integrity, and does not require de novo protein synthesis. Recently our data (Alnemri, E. S., and Litwack, G. (1989) J. Biol. Chem. 264, 4104-4111) suggested that activation of DNA cleavage in CEM-C7 lymphocytes by glucocorticoids is independent of calcium uptake. Similarly, the novobiocin effect is also independent of calcium uptake and does not occur in isolated CEM nuclei or in CEM cells treated previously with the divalent cation ionophore A23187. Internucleosomal DNA cleavage induced by novobiocin or glucocorticoid generates blunt-ended double-stranded DNA fragments possessing 3'-hydroxyls and 5'-phosphates. As demonstrated by gel retardation analysis and DNase I footprinting, novobiocin causes the disruption and unfolding of an in vitro reconstituted mononucleosome so that it becomes more susceptible to DNase I cleavage. Our data suggest that 1) novobiocin rapid activation of internucleosomal DNA cleavage and chromatin changes in CEM lymphocytes are molecular features of apoptosis or programmed cell death. 2) CEM lymphocytes apparently do not express a Ca2(+)-dependent endonuclease. 3) The mechanism(s) of glucocorticoid or novobiocin-induced DNA cleavage in CEM lymphocytes involves activation of a constitutive non Ca2(+)-dependent endonuclease. We propose that the majority of nuclear chromatin is maintained in a highly compact and charge-neutralized state and that disruption of this highly ordered structure, directly by novobiocin or indirectly by glucocorticoid, may lead to the exposure and unmasking of internucleosomal linker DNA regions which are substrates for a constitutive non-Ca2(+)-dependent endonuclease.     

Regulation of apoptosis in S49 cells

Apoptosis, or programmed cell death, is a highly regulated physiological process by which individual cells die and are removed from a given population. This process, defined by both morphological and biochemical characteristics, has been extensively studied in the glucocorticoid-induced immature thymocyte model. In the present study we explore the effects of glucocorticoids on variants of the S49.1 thymocyte without (S49-NEO) or with (S49-bcl-2) the bcl-2 proto-oncogene. In S49-NEO cells dexamethasone induced a time- and dose-dependent loss of viability and increase in DNA internucleosomal fragmentation (a biochemical hallmark of apoptosis). Glucocorticoid treatment was also associated with an apoptotic morphology (cell shrinkage, chromatin condensation) and the effects of this steroid could be reversed by the glucocorticoid antagonist RU486. In contrast, S49-bcl-2 cells showed no change in viability, DNA fragmentation or apoptotic morphology. Interestingly, the apoptotic effects of glucocorticoid in S49-NEO cells were mimicked by the translation inhibitor cycloheximide and the zinc chelator 1,10-phenanthroline, suggesting that zinc and translational events are necessary to maintain the nonapoptotic state. Finally, nuclease activity was extracted from glucocorticoid-treated S49-NEO cells but not control cells. Together the results further define the effects of glucocorticoids on these cells and provide insight into the mechanisms controlling apoptosis.     

High and low molecular weight DNA cleavage in ovarian granulosa cells: characterization and protease modulation in intact cells and in cell-free nuclear autodigestion assays

To continue elucidation of the biochemical and molecular pathways involved in the induction of apoptosis in granulosa cells (GC) of ovarian follicles destined for atresia, we characterized the occurrence and protease modulation of high and low molecular weight (MW) DNA fragmentation during rat GC death. Atresia of ovarian follicles, occurring either spontaneously in vivo or induced in vitro, was associated with both high MW and internucleosomal (low MW) DNA cleavage. Incubation of follicles in the presence of a putative irreversible and non-competitive inhibitor of caspase-1 (interleukin-1beta-converting enzyme or ICE), sodium aurothiomalate (SAM), completely prevented internucleosomal, but not high MW, DNA cleavage. As reported previously, morphological features of apoptosis (pyknosis, cellular condensation) and atresia (granulosa cell disorganization, oocyte pseudomaturation) remained detectable in SAM-treated follicles. The potential involvement of proteases in endonuclease activation was further analyzed in cell-free assays using nuclei from both GC (which autodigest their DNA) and HeLa cells (HC, which do not autodigest their DNA unless incubated with extracts prepared from other cell types). Crude cytoplasmic extracts prepared from GC induced both high MW and internucleosomal DNA cleavage in HC nuclei. The induction of low, but not high, MW DNA cleavage in HC nuclei by GC extracts was suppressed by pretreatment of the extracts with SAM or with any one of the serine protease inhibitors, dichloroisocoumarin (DCI), N-tosyl-L-leucylchloromethylketone (TLCK) or N-tosyl-L-phenylchloromethylketone (TPCK). Interestingly, SAM and DCI also prevented cation-induced low MW DNA fragmentation in GC nuclei; however, TLCK and TPCK were without effect. Our results support a role for cytoplasmic and nuclear serine proteases in the activation of the endonuclease(s) responsible for internucleosomal DNA cleavage during apoptosis.     

Characterization of apoptosis-like endonuclease activity in avian thymocytes.

In the current study the internucleosomal DNA cleavage activity associated with apoptosis was investigated in avian thymocytes. Thymocyte nuclear proteins from glucocorticoid-treated chickens were incubated with chicken red blood cell (cRBC) nuclei, and DNA degradation was analyzed by agarose gel electrophoresis and fluorescence-activated flow cytometry. The thymocyte nuclear extract contained an endonuclease activity that degraded cRBC chromatin at internucleosomal sites as detected by agarose gel electrophoresis. Flow cytometry analysis of cRBC nuclei that were treated with thymocyte nuclear proteins demonstrated a loss of cellular DNA as a function of the amount of added nuclease activity. Furthermore, it was demonstrated that the thymocyte nuclear extract contained a nuclease activity that was capable of degrading radiolabelled naked 32P-DNA into acid soluble DNA fragments. All three assay methods demonstrate that the thymocyte nuclease activity can be inhibited by EDTA, zinc ions and the nuclease inhibitor aurintricarboxylic acid. Based on the analysis of cofactor requirement of this nuclease activity and its susceptibility to inhibitors, the endonuclease activity present in avian apoptotic thymocytes appears to be identical to the mammalian counterpart.     

Functional characterization of DNase X, a novel endonuclease expressed in muscle cells

The activation of endonucleases resulting in the degradation of genomic DNA is one of the most characteristic changes in apoptosis. Here, we report the characterization of a novel endonuclease, termed DNase X due to its X-chromosomal localization. The active nuclease is a 35 kDa protein with 39% identity to DNase I. When incubated with isolated nuclei, recombinant DNase X was capable of triggering DNA degradation at internucleosomal sites. Similarly to DNase I, the nuclease activity of DNase X was dependent on Ca(2+) and Mg(2+) and inhibited by Zn(2+) ions or chelators of bivalent cations. Overexpression of DNase X caused internucleosomal DNA degradation and induction of cell death associated with increased caspase activation. Despite the presence of two potential caspase cleavage sites, DNase X was processed neither in vitro nor in vivo by different caspases. Interestingly, after initiation of apoptosis DNase X was translocated from the cytoplasm to the nuclear compartment and aggregated as a detergent-insoluble complex. Abundant expression of DNase X mRNA was detected in heart and skeletal muscle cells, suggesting that DNase X may be involved in apoptotic or other biological events in muscle tissues.     

N-(2-mercaptoethyl)-1,3-propanediamine (WR-1065) protects thymocytes from programmed cell death.

Gamma-irradiation, glucocorticoid hormones, and calcium ionophores stimulate a suicide process in thymocytes, known as apoptosis or programmed cell death, that involves internucleosomal DNA fragmentation by a Ca(2+)- and Mg(2+)-dependent nuclear endonuclease. In this study we report that N-(2-mercaptoethyl)-1,3-propanediamine (WR-1065) blocked DNA fragmentation and cell death in thymocytes exposed to gamma-radiation, dexamethasone, or calcium ionophore A23187. WR-1065 protected the thymocytes from radiation-induced apoptosis when incubated with cells after irradiation but not before and/or during irradiation. WR-1065 inhibited Ca(2+)- and Mg(2+)-dependent DNA fragmentation in isolated thymocyte nuclei. Our results suggest that WR-1065 protects thymocytes from apoptosis by inhibiting Ca(2+)- and Mg(2+)-dependent nuclear endonuclease action.     

Possible involvement of cyclophilin B and caspase-activated deoxyribonuclease in the induction of chromosomal DNA degradation in TCR-stimulated thymocytes

TCR engagement of immature CD4(+)CD8(+) thymocytes induces clonal maturation (positive selection) as well as clonal deletion (negative selection) in the thymus. However, the cell death execution events of thymocytes during the negative selection process remain obscure. Using a cell-free system, we identified two different DNase activities in the cytosol of in vivo anti-TCR-stimulated murine thymocytes: one that induced chromosomal DNA fragmentation, which was inhibited by an inhibitor of caspase-activated DNase, and another that induced plasmid DNA degradation, which was not inhibited by an inhibitor of caspase-activated DNase. We purified the protein to homogeneity that induced plasmid DNA degradation from the cytosol of anti-CD3-stimulated thymocytes and found that it is identical with cyclophilin B (Cyp B), which was reported to locate in endoplasmic reticulum. Ab against Cyp B specifically inhibited the DNA degradation activity in the cytosol of anti-CD3-stimulated thymocytes. Furthermore, recombinant Cyp B induced DNA degradation of naked nuclei, but did not induce internucleosomal DNA fragmentation. Finally, we demonstrated that TCR engagement of a murine T cell line (EL4) with anti-CD3/CD28 resulted in the release of Cyp B from the microsome fraction to the cytosol/nuclear fraction. Our data strongly suggest that both active caspase-activated DNase and Cyp B may participate in the induction of chromosomal DNA degradation during cell death execution of TCR-stimulated thymocytes.     

Identification, purification, and characterization of a calcium-dependent endonuclease (NUC18) from apoptotic rat thymocytes. NUC18 is not histone H2B

Glucocorticoids stimulate apoptosis in rat thymocytes that is characterized by internucleosomal DNA degradation. We have previously identified an 18-kDa calcium-dependent nuclease whose activity is associated with this DNA degradation. The existence of this nuclease has been challenged by Alnemri and Litwack (1989) J. Biol. Chem. 264, 4104-4111, who suggest that the nuclease we observed was histone H2B. We report here a modified nuclease assay which uses [32P] DNA as a substrate that has enabled the purification and characterization of the 18-kDa nuclease (NUC18). Using Bio-Rex 70 chromatography in conjunction with this assay, we show that NUC18 can be separated from histone H2B. Enzymatically active NUC18, purified to apparent homogeneity, failed to react with two different anti-histone H2B antibodies. NUC18 was inactive in the absence of calcium and known inhibitors of apoptosis, i.e. zinc and aurintricarboxylic acid inhibit its activity. Although NUC18 activity was detected in nuclear extracts of thymocytes of both control and glucocorticoid-treated thymocytes, these activities were distinct. Gel filtration analysis revealed that NUC18 was present as a high molecular weight complex (greater than 100 kDa) in both groups of cells, whereas it also existed as a low molecular weight form in glucocorticoid-treated cells. Thus, NUC18 remains a candidate for the endonuclease responsible for the DNA degradation component of the apoptotic process.     

Progesterone receptor-mediated inhibition of apoptosis in granulosa cells isolated from rats treated with human chorionic gonadotropin

Almost all ovarian follicles undergo atresia during follicular development. However, the number of corpora lutea roughly equals the number of preovulatory follicles in the ovary. Because apoptosis is the cellular mechanism behind follicle and luteal cell demise, this suggests a change in apoptosis susceptibility during the periovulatory period. Sex steroids are important regulators of follicular cell survival and apoptosis. The aim of the present work was to study the role of progesterone receptor-mediated effects in the regulation of granulosa cell apoptosis. The levels of internucleosomal DNA fragmentation were evaluated in rat granulosa cells before and after induction of the nuclear progesterone receptor, using hCG treatment to eCG-primed rats to mimic the naturally occurring LH surge. Granulosa cells isolated from hCG-treated rats showed a several-fold increase in the expression of progesterone receptor mRNA and a 47% decrease (P < 0.01) in DNA fragmentation after 24 h incubation in serum-free medium compared to granulosa cells isolated from rats treated with eCG only. The effect of hCG treatment in vivo was dose-dependently reversed in vitro by addition of antiprogestins (Org 31710 or RU 486) to the culture medium, demonstrated by increased DNA fragmentation as well as increased caspase-3 activity. Addition of antiprogestins to granulosa cells isolated from immature or eCG-treated rats did not result in increased DNA fragmentation. The results suggest that progesterone receptor-mediated effects are involved in regulating the susceptibility to apoptosis in LH receptor-stimulated preovulatory rat granulosa cells.     

Cell nucleus and DNA fragmentation are not required for apoptosis

Apoptosis is the predominant form of cell death and occurs under a variety of physiological and pathological conditions. Cells undergoing apoptotic cell death reveal a characteristic sequence of cytological alterations including membrane blebbing and nuclear and cytoplasmic condensation. Activation of an endonuclease which cleaves genomic DNA into internucleosomal DNA fragments is considered to be the hallmark of apoptosis. However, no clear evidence exists that DNA degradation plays a primary and causative role in apoptotic cell death. Here we show that cells enucleated with cytochalasin B still undergo apoptosis induced either by treatment with menadione, an oxidant quinone compound, or by triggering APO-1/Fas, a cell surface molecule involved in physiological cell death. Incubation of enucleated cells with the agonistic monoclonal anti-APO-1 antibody revealed the key morphological features of apoptosis. Moreover, in non-enucleated cells inhibitors of endonuclease blocked DNA fragmentation, but not cell death induced by anti-APO-1. These data suggest that DNA degradation and nuclear signaling are not required for induction of apoptotic cell death.     

Characterization of the endogenous deoxyribonuclease involved in nuclear DNA degradation during apoptosis (programmed cell death).

Cell death by apoptosis occurs in a wide range of physiological events including repertoire selection of lymphocytes and during immune responses in vivo. A hallmark of apoptosis is the internucleosomal DNA degradation for which a Ca2+,Mg(2+)-dependent endonuclease has been postulated. This nuclease activity was extracted from both rat thymocyte and lymph node cell nuclei. When incubated with nuclei harbouring only limited amounts of endogenous nuclease activity, the ladder pattern of DNA fragments characteristic of apoptosis was induced. This extractable nucleolytic activity was immunoprecipitated with antibodies specific for rat deoxyribonuclease I (DNase I) and was inhibited by actin in complex with gelsolin segment 1, strongly pointing to the presence of a DNase I-type enzyme in the nuclear extracts. COS cells transiently transfected with the cDNA of rat parotid DNase I expressed the enzyme, and their nuclei were able to degrade their DNA into oligosome-sized fragments. PCR analysis of mRNA isolated from thymus, lymph node cells and kidney yielded a product identical in size to that from rat parotid DNase I. Immunohistochemical staining with antibodies to rat DNase I confirmed the presence of DNase I antigen in thymocytes and lymph node cells. The tissue distribution of DNase I is thus extended to tissues with no digestive function and to cells which are known to be susceptible to apoptosis. We propose that during apoptosis, an endonuclease indistinguishable from DNase I gains access to the nucleus due to the breakdown of the ER and the nuclear membrane.     

Glucocorticoid activation of a calcium-dependent endonuclease in thymocyte nuclei leads to cell death

Dexamethasone and corticosterone kill mouse thymocytes, as measured by eosin uptake, after several hours of in vitro incubation. This killing requires RNA and protein synthesis, because it is inhibited by cycloheximide, emetine, or actinomycin D. An earlier event than cell death is the extensive fragmentation of nuclear DNA into oligonucleosomal subunits; this fragmentation also requires RNA and protein synthesis. The DNA cleavage results from the action of an endonuclease that preferentially cleaves DNA in the linker regions between nucleosomes. This endonuclease is found constitutively in the nuclei of thymocytes and some other cells, and requires calcium and magnesium ions for its activation; if isolated fresh thymocyte nuclei are incubated with these ions, as much as 77% of their DNA is cleaved within 90 min. Thus, the protein for which synthesis is necessary for glucocorticoid-induced thymocyte death is not the endonuclease itself, but is in some way involved in its activation; we suggest that it may be part of a system for transporting calcium into the nucleus. The endonuclease is inhibited by zinc, which also prevents thymocyte death. It appears that glucocorticoids cause thymocyte death by activating an enzyme that rapidly and extensively degrades DNA. This "death from within" is biochemically and morphologically different from toxic or accidental cell death, such as that induced by azide, heat, or antibody and complement treatment. Although mature T cells also contain the endogenous endonuclease, they lack the glucocorticoid-inducible mechanism for activating it, and are thus glucocorticoid-resistant.     

An endogenous calcium-dependent, caspase-independent intranuclear degradation pathway in thymocyte nuclei: antagonism by physiological concentrations of K(+) ions

Calcium ions have been implicated in apoptosis for many years, however the precise role of this ion in the cell death process remains incomplete. We have extensively examined the role of Ca(2+) on nuclear degradation in vitro using highly purified nuclei isolated from non-apoptotic rat thymocytes. We show that these nuclei are devoid of CAD (caspase-activated DNase), and DNA degradation occurs independent of caspase activity. Serine proteases rather than caspase-3 appear necessary for this Ca(2+) -dependent DNA degradation in nuclei. We analyzed nuclei treated with various concentrations of Ca(2+) in the presence of both a physiological (140 mM) and apoptotic (40 mM) concentration of KCl. Our results show that a 5-fold increase in Ca(2+) is required to induce DNA degradation at the physiological KCl concentration compared to the lower, apoptotic concentration of the cation. Ca(2+) -induced internucleosomal DNA degradation was also accompanied by the release of histones, however the apoptotic-specific phosphorylation of histone H2B does not occur in these isolated nuclei. Interestingly, physiological concentrations of K(+) inhibit both Ca(2+) -dependent DNA degradation and histone release suggesting that a reduction of intracellular K(+) is necessary for this apoptosis-associated nuclear degradation in cells. Together, these data define an inherent caspase-independent catabolic pathway in thymocyte nuclei that is sensitive to physiological concentrations of intracellular cations.     

The nucellus degenerates by a process of programmed cell death during the early stages of wheat grain development

The nucellus, which is the maternal tissue of the wheat grain, degenerates during the early stages of development. We have investigated whether or not this degenerative process may be considered as programmed cell death (PCD). The analysis of DNA of tissues dissected from developing wheat (Triticum aestivum L. cv Chinese Spring) grains at 5-20 days post anthesis (dpa) showed the presence of DNA laddering, which is indicative of internucleosomal fragmentation of nuclear DNA, in maternal tissues but not in the endosperm. The TUNEL assay showed in-situ internucleosomal fragmentation of DNA in nuclei of parenchymal and epidermal cells of the nucellus, as well as in the pericarp, during the early stages of grain development (5 dpa). Furthermore, internucleosomal fragmentation of nuclear DNA was observed in nucellar projection cells in the middle stages of grain development (13-18 dpa), thus showing a process of PCD in these maternal tissues. Electron-transmission microscopy analysis allowed the morphology of PCD to be characterized in this plant tissue. Initially, fragmentation of the cytoplasm was observed, the nuclear envelope appeared dilated and to be forming vacuoles, and the content of heterochromatin increased. A progressive degradation of the cytosolic contents and organelles was observed, and the plasma membrane was disrupted. However, the Golgi apparatus remained intact and apparently functional even in the final stages of cell death.